B-cell subsets responsive to fluorescein-conjugated antigens. I. Sensitivity to anti-IgD, tolerance, and cross-priming

Human peripheral blood monocyte-depleted lymphocytes, T lymphocytes, and non-T lyphocytes were studied for their locomotor activity in response to several common chemotactic stimuli. The factors used to stimulate lymphocyte locomotion were casein, C5a, and f-Met-Leu-Phe. Chemotaxis (directional locomotion) as well as chemokinesis (nondirectional locomotion) in response to each factor were delineated. Monocyte-depleted lymphocyte locomotion was stimulated significantly by all of the above factors. Separation of lymphocytes into T cells and non-T cells indicated that T-lymphocyte locomotion was stimulated by casein and C5a but not by f-Met-Leu-Phe. Non-T lymphocytes were found to respond to C5a and f-Met-Leu-Phe but responded minimally to casein. Additional experiments indicated that casein and f-Met-Leu-Phe were chemokinetic for both monocyte-depleted lymphocytes and non-T lymphocytes, while C5a was chemotactic for both monocyte-depleted lymphocyte preparations and purified T cells.     

Chemotropism indices for polymorphonuclear leukocytes.

Trajectories of polymorphonuclear leukocytes which are responding to a chemical gradient are analyzed in order to deduce probability distributions of the angles between successive path segments. The turn angle probability distributions thus obtained are seen to be strongly dependent on the direction of locomotion prior to a turn, in that cells usually turn to maintain alignment along an axis directed towards the chemoattractant source. A mathematical model based on these observations is developed in order to understand the relationship between net chemotactic response and parameters characterizing stochastic movements of individual cells. In particular, the manner in which the chemotropism index depends on details of the turn-angle distributions is examined. When bias in the direction of turn is induced by a chemotactic field, transition from random motion to directed response occurs most abruptly if the turn-angle distribution is narrow. "Accommodation," viz., a dependence of the mean angle of turn upon prior orientation, is found to have relatively little effect on the magnitude of the response.     

How do leucocytes perceive chemical gradients?

Chemoattractants determine not only the direction of leucocyte locomotion (chemotaxis) but also its speed (chemokinesis). Various mechanisms by which leucocytes may detect chemotactic gradients, including spatial and temporal detection, are briefly reviewed. These mechanisms as originally proposed did not address the question how attractants cause leucocytes to migrate in persistent random paths in the absence of a gradient. Stochastic models have recently been presented in which leucocytes either respond by polarizing and migrating in the direction from which they receive their first signal, or respond to random fluctuations in the perceived attractant concentration. Stochastic models allow an explanation for the persistent random walk shown by cells in uniform concentrations of attractant as well as for directional locomotion in gradients. They suggest that, at the biochemical level, the mechanisms by which attractants stimulate chemotaxis and chemokinesis are probably the same.     

How do leucocytes perceive chemical gradients?

Abstract Chemoattractants determine not only the direction of leucocyte locomotion (chemotaxis) but also its speed (chemokinesis). Various mechanisms by which leucocytes may detect chemotactic gradients, including spatial and temporal detection, are briefly reviewed. These mechanisms as originally proposed did not address the question how attractants cause leucocytes to migrate in persistent random paths in the absence of a gradient. Stochastic models have recently been presented in which leucocytes either respond by polarizing and migrating in the direction from which they receive their first signal, or respond to random flucuations in the perceived attractant concentration. Stochastic models allow an explanation for the persistent random walk shown by cells in uniform concentrations of attractant as well as for directional locomotion in gradients. They suggest that, at the biochemical level, the mechanisms by which attractants stimulate chemotaxis and chemokinesis are probably the same.     

Binding of protein chemotactic factors to the surfaces of neutrophil leukocytes and its modification with lipid-specific bacterial toxins

Summary The binding to neutrophil leukocytes of human serum albumin (HSA), which is chemokinetic for leukocytes, i.e. influences their rate of locomotion, and of alkali-denatured HSA, which is chemotactic for leukocytes, i.e. influences their direction of locomotion, was studied. Native serum albumin showed low affinity binding to the neutrophil surface. Denatured serum albumin showed saturable binding with a K_a of approximately 10⁶ litres per mole to about 10⁶ binding sites per cell. Another protein chemotactic factor, _s-casein, gave similar binding. These results exclude that chemotactic reactions to denatured proteins are mediated in a completely non-specific manner and suggest the presence on the cell of a restricted number of defined recognition sites. Binding was reduced following treatment of the cells with either of two lipid-specific bacterial toxins, perfringolysin, the -toxin of Clostridium perfringens, an oxygen-labile cholesterol-specific toxin, and Staphylococcus aureus Sphingomyelinase C. Both have previously been shown to reduce chemotactic reactions and both were used at doses which did not reduce cell viability. These results suggest an important, and possibly direct, role for membrane lipid in the binding sites for chemotactic factors. Visual analysis of the behaviour of perfringolysin-treated neutrophils showed that these cells were still capable of chemotactic locomotion. The cells appeared to be less efficient than normal in detecting chemotactic gradients only when at a distance from the gradient source, a finding which is consistent with reduced binding of the chemotactic factor to the cell surface.     

Turn costs change the value of animal search paths

The tortuosity of the track taken by an animal searching for food profoundly affects search efficiency, which should be optimised to maximise net energy gain. Models examining this generally describe movement as a series of straight steps interspaced by turns, and implicitly assume no turn costs. We used both empirical‐ and modelling‐based approaches to show that the energetic costs for turns in both terrestrial and aerial locomotion are substantial, which calls into question the value of conventional movement models such as correlated random walk or Lévy walk for assessing optimum path types. We show how, because straight‐line travel is energetically most efficient, search strategies should favour constrained turn angles, with uninformed foragers continuing in straight lines unless the potential benefits of turning offset the cost.     

The Glucose Concentration Modulates N-Formyl-Methionyl-Leucyl-Phenylalanine (fMet-Leu-Phe)-Stimulated Chemokinesis in Normal Human Neutrophils

The effects of glucose concentration on the chemokinetic effects of the chemotactic peptide N-formyl-methionyl-leucyl-phenylalanine (fMet-Leu-Phe) was evaluated for normal human neutrophils using a direct microscopic assay. fMet-Leu-Phe increased the rate of locomotion in the absence of glucose, but the chemokinetic effect of fMet-Leu-Phe was most potent at 5mM glucose and not further changed at 15 mM glucose. The chemokinetic effects of fMet-Leu-Phe and glucose were essentially the same in blood clot-isolated and gradient-isolated neutrophils. However, in gradient-isolated neutrophils, the rate of locomotion under different experimental conditions was strictly negatively correlated to the fraction of non-locomoting cells and the degree of adhesion to the substratum. These results indicate that the chemokinetic effects of fMet-Leu-Phe are regulated by the glucose concentration by inducing locomotor activity in otherwise non-locomoting cells and by improving adhesion to the substratum.     

Locomotion of white blood cells: a biophysical analysis

We determined some biophysical properties of human granulocytes, monocytes, and lymphocytes in respect to their locomotion. Granulocytes were exposed to plasma and were allowed to crawl on uncoated or glycol methacrylate coated glass plates. Monocytes did not migrate on uncoated glass, but did so on glycol methacrylated glass. Lymphocytes did not move on glass or glycol methacrylated glass, but moved on plexiglas coverslips. Granulocytes and monocytes showed a pronounced, directed movement towards a lysed erythrocyte (necrotaxis), lymphocytes showed no necrotactic response. The information collected by the granulocytes and monocytes in the necrotactic gradient was between 1 and 2 bits. This small amount of information indicated that the cellular decision in favor of a new direction of migration is based on a mechanism involving instability. We showed that the necrotactic response of granulocytes and monocytes is the product of the chemokinetic activity and the polar order parameter (= McCutcheon index) indicating that the cellular decision for a new direction of migration is independent of the speed of the cell movement. The movement of monocytes can be characterized in a similar way to that of granulocytes: the angle of deviation from a straight line path is nearly a fixed value (+/- 35 degrees). Lymphocytes stay in a restricted area after straight line movement. Particular attention was focused on cellular properties involved in locomotion. The characteristic time of the internal clock controlling the locomotion was 0.9 minutes for granulocytes and 2 minutes for monocytes. We were not able to determine the characteristic time of lymphocytes. We were able to determine the internal program responsible for the change in direction of movement. The directional memory time for granulocytes was 0.9 minutes. Monocytes had two directional memory times, short (2 minutes) and long (greater than 18 minutes). Lymphocytes had a very short directional memory time of 40 seconds. The distribution of the track velocities of migrating granulocytes and monocytes was described by bell shaped curves indicating homogeneous populations of cells. The distribution for lymphocytes had two maxima.     

Wet and dry bacterial spore densities determined by buoyant sedimentation.

The wet densities of various types of dormant bacterial spores and reference particles were determined by centrifugal buoyant sedimentation in density gradient solutions of three commercial media of high chemical density. With Metrizamide or Renografin, the wet density values for the spores and permeable Sephadex beads were higher than those obtained by a reference direct mass method, and some spore populations were separated into several density bands. With Percoll, all of the wet density values were about the same as those obtained by the direct mass method, and only single density bands resulted. The differences were due to the partial permeation of Metrizamide and Renografin, but not Percoll, into the spores and the permeable Sephadex beads. Consequently, the wet density of the entire spore was accurately represented only by the values obtained with the Percoll gradient and the direct mass method. The dry densities of the spores and particles were determined by gravity buoyant sedimentation in a gradient of two organic solvents, one of high and the other of low chemical density. All of the dry density values obtained by this method were about the same as those obtained by the direct mass method.     

The influence of contact guidance on chemotaxis of human neutrophil leukocytes

Chemotaxis of human neutrophil leukocytes moving on or in aligned 3D fibrin gels is more efficient if the cells are moving along the axis of fibre alignment than if they have to cross the fibres. This was shown by using two assays, one in which the cells were responding to a distant (600 micrometers) gradient source diffusing from a filter paper impregnated with formyl-Met-Leu-Phe and incorporated into the gel, the other in which the cells were responding to nearby (20--30 micrometers) Candida albicans spores in serum. In the former assay, impairment of chemotaxis across the axis of fibre alignment was highly significant. In the latter, cells showed efficient chemotaxis to the spores, but took more irregular paths when crossing the aligned fibres than when running along them. Neutrophils show contact guidance in aligned collagen or fibrin gels (Wilkinson et al., Exp cell res 140 (1982) 55) [1], thus the cells were subjected simultaneously to two directional cues in these experiments, one the chemotactic gradient and the other a contact guidance field. These cues may reinforce or interfere with each other depending on their relative orientation. Since many tissues in vivo show alignment or more complex forms of patterning, tissue architecture is likely to be an important determinant of the efficiency of cellular mobilization in inflamed or infected sites.     

3'-phosphoinositides regulate the coordination of speed and accuracy during chemotaxis

The PI3K/PTEN pathway, as the regulator of 3′-phosphoinositide (3′-PI) dynamics, has emerged as a key regulator of chemoattractant gradient sensing during chemotaxis in Dictyostelium and other cell types. Previous results have shown 3′-PIs to be important for regulating basal cell motility and sensing the direction and strength of the chemoattractant gradient. We examined the chemotaxis of wild-type cells and cells lacking PTEN or PI3K1 and 2 using analytical methods that allowed us to quantitatively discern differences between the genotype's ability to sense and efficiently respond to changes in gradient steepness during chemotaxis. We found that cells are capable of increasing their chemotactic accuracy and speed as they approach a micropipette in a manner that is dependent on the increasing strength of the concentration gradient and 3′-PI signaling. Further, our data show that 3′-PI signaling affects a cell's ability to coordinate speed and direction to increase chemotactic efficiency. Using to our knowledge a new measurement of chemotactic efficiency that reveals the degree of coordination between speed and accuracy, we found that cells also have the capacity to increase their chemotactic efficiency as they approach the micropipette. Like directional accuracy and speed, the increase in chemotactic efficiency of cells with increased gradient strength is sensitive to 3′-PI dysregulation. Our evidence suggests that receptor-driven 3′-PI signaling regulates the ability of a cell to capitalize on stronger directional inputs and minimize the effects of inaccurate turns to increase chemotactic efficiency.     

Alteration of rat splenic lymphocyte migration in vitro by the state of microtubule integrity

Rat splenic lymphocytes exhibit a positive chemokinetic response to colchicine and vinblastine. Both agents elicit a dose-dependent increase in chemokinesis with their peak effect at 2 to 4 × 10^?7M being 3.5 times baseline random migration. The distance traveled by the leading front and the total movement of rat splenic lymphocytes is maximal in the absence of a gradient at all effective concentrations of colchicine or vinblastine. Checkerboard analysis established this response as entirely chemokinetic without any chemotactic component. That this chemokinetic response was due to a shift in the dynamic state of microtubules toward disassembly was supported by the inactivity of lumicolchicine and the capacity of heavy water to reverse the effect in a dose-response fashion. Cytochalasin B suppressed baseline random migration and reversed the chemokinetic response of the rat splenic lymphocytes to 4 × 10^?7M colchicine. The chemokinetic motility of rat splenic lymphocytes may depend not only on microtubule disassembly but also on the contractile activity of microfilaments.     

Chemotaxis with directional sensing during Dictyostelium aggregation

We show that the chemotactic movements of colonies of the starving amoeba Dictyostelium discoideum are driven by a force that depends on both the direction of propagation (directional sensing) of reaction-diffusion chemotactic waves and on the gradient of the concentration of the chemoattractant, solving the chemotactic wave paradox. It is shown that the directional sensing of amoebae is due to the sensitivity of the cells to the time variation of the concentration of the chemoattractant combined with its spatial gradient. It is also shown that chemotaxis exclusively driven by local concentration gradient leads to unstable local motion, preventing cells from aggregation. These findings show that the formation of mounds, which initiate multicellularity in Dictyostelium discoideum, is caused by the sensitivity of the amoebae due to three factors, namely, to the direction of propagation of the chemoattractant, to its spatial gradient, and to the emergence of cAMP “emitting centres”, responsible for the local accumulation of the amoebae.     

Wet and dry bacterial spore densities determined by buoyant sedimentation

The wet densities of various types of dormant bacterial spores and reference particles were determined by centrifugal buoyant sedimentation in density gradient solutions of three commercial media of high chemical density. With Metrizamide or Renografin, the wet density values for the spores and permeable Sephadex beads were higher than those obtained by a reference direct mass method, and some spore populations were separated into several density bands. With Percoll, all of the wet density values were about the same as those obtained by the direct mass method, and only single density bands resulted. The differences were due to the partial permeation of Metrizamide and Renografin, but not Percoll, into the spores and the permeable Sephadex beads. Consequently, the wet density of the entire spore was accurately represented only by the values obtained with the Percoll gradient and the direct mass method. The dry densities of the spores and particles were determined by gravity buoyant sedimentation in a gradient of two organic solvents, one of high and the other of low chemical density. All of the dry density values obtained by this method were about the same as those obtained by the direct mass method.     

Cellular aggregation towards steady point sources of attractant.

The aggregation of a layer of chemotactically sensitive cells towards a steady point source of a chemical attractant (acrasin), a phenomenon exhibited, for instance, by the cellular slime mould Dictyostelium minutum, is treated analytically. An acrasin gradient is set up by diffusion from the source, taken to be a continuous one of constant strength. The aggregative movement of the cells in response to the gradient is expressed in terms of chemotactic laws and the random movement taken into account through a diffusion coefficient. Various chemotactic laws are considered [response velocity (1) proportional to the relative acrasin gradient, (2) proportional to the gradient (3) constant or maximal]; the resulting partial differential equations are solved to obtain the time dependence for the number of cells in the aggregate. Each law yields a characteristic time dependence, the dominant term of which is ～ t^a, 0 < α ? 2.     

Neural Basis of Stimulus-Angle-Dependent Motor Control of Wind-Elicited Walking Behavior in the Cricket Gryllus bimaculatus

Crickets exhibit oriented walking behavior in response to air-current stimuli. Because crickets move in the opposite direction from the stimulus source, this behavior is considered to represent ‘escape behavior’ from an approaching predator. However, details of the stimulus-angle-dependent control of locomotion during the immediate phase, and the neural basis underlying the directional motor control of this behavior remain unclear. In this study, we used a spherical-treadmill system to measure locomotory parameters including trajectory, turn angle and velocity during the immediate phase of responses to air-puff stimuli applied from various angles. Both walking direction and turn angle were correlated with stimulus angle, but their relationships followed different rules. A shorter stimulus also induced directionally-controlled walking, but reduced the yaw rotation in stimulus-angle-dependent turning. These results suggest that neural control of the turn angle requires different sensory information than that required for oriented walking. Hemi-severance of the ventral nerve cords containing descending axons from the cephalic to the prothoracic ganglion abolished stimulus-angle-dependent control, indicating that this control required descending signals from the brain. Furthermore, we selectively ablated identified ascending giant interneurons (GIs) in vivo to examine their functional roles in wind-elicited walking. Ablation of GI8-1 diminished control of the turn angle and decreased walking distance in the initial response. Meanwhile, GI9-1b ablation had no discernible effect on stimulus-angle-dependent control or walking distance, but delayed the reaction time. These results suggest that the ascending signals conveyed by GI8-1 are required for turn-angle control and maintenance of walking behavior, and that GI9-1b is responsible for rapid initiation of walking. It is possible that individual types of GIs separately supply the sensory signals required to control wind-elicited walking.     

rC5a directs the in vitro migration of human memory and naive tonsillar B lymphocytes: implications for B cell trafficking in secondary lymphoid tissues.

Human C5a is a potent chemoattractant for granulocytes, monocytes, and dendritic cells. In mice C5a has been shown to be chemotactic for germinal center (GC) B cells. To date, no information is available on the effects of C5a on human B cell locomotion. Here we demonstrate that rC5a increases polarization and migration of human tonsillar B cells. The locomotory response was due to both chemokinetic and chemotactic activities of rC5a. Moreover, memory and, at a lesser extent, naive B cell fractions from purified tonsillar populations displayed rC5a-enhanced migratory properties, whereas GC cells did not. Flow cytometry revealed C5aR (CD88) on approximately 40% memory and 10% naive cells, respectively, whereas GC cells were negative. Immunohistochemistry showed that a few CD88+ cells were of the B cell lineage and localized in tonsillar subepithelial areas, where the majority of memory B cells settle. Pretreatment of memory B cells with the CD88 mAb abolished their migratory responsiveness to rC5a. Finally, the C5 gene was found to be expressed in naive, GC, and memory B lymphocytes at both the mRNA and the protein level. This study delineates a novel role for C5a as a regulator of the trafficking of human memory and naive B lymphocytes and supports the hypothesis that the B cells themselves may serve as source of C5 in secondary lymphoid tissues.     

Biased reorientation in the chemotaxis of peritrichous bacteria Salmonella enterica serovar Typhimurium

Many kinds of peritrichous bacteria that repeat runs and tumbles by using multiple flagella exhibit chemotaxis by sensing a difference in the concentration of the attractant or repellent between two adjacent time points. If a cell senses that the concentration of an attractant has increased, their flagellar motors decrease the switching frequency from counterclockwise to clockwise direction of rotation, which causes a longer run in swimming up the concentration gradient than swimming down. We investigated the turn angle in tumbles of peritrichous bacteria swimming across the concentration gradient of a chemoattractant because the change in the switching frequency in the rotational direction may affect the way tumbles. We tracked several hundreds of runs and tumbles of single cells of Salmonella enterica serovar Typhimurium in the concentration gradient of L-serine and found that the turn angle depends on the concentration gradient that the cell senses just before the tumble. The turn angle is biased toward a smaller value when the cells swim up the concentration gradient, whereas the distribution of the angle is almost uniform (random direction) when the cells swim down the gradient. The effect of the observed bias in the turn angle on the degree of chemotaxis was investigated by random walk simulation. In the concentration field where attractants diffuse concentrically from the point source, we found that this angular distribution clearly affects the reduction of the mean-square displacement of the cell that has started at the attractant source, that is, the bias in the turn angle distribution contributes to chemotaxis in peritrichous bacteria.     

A subpopulation analysis of f-MLP stimulated granulocytes migrating in filters

Leukocyte migration in vitro has been studied extensively during many years without providing satisfactory theoretical models for the different migratory behaviors (chemotaxis and chemokinesis) of leukocyte populations. The present study utilized the fluid gradient chamber, which is a new method to study leukocyte migration in filters. Human neutrophils were applied between two stacked filters and migrated in all directions under the influence of constant concentrations or chemotactic gradients of f-MLP, maintained in fluid phase density gradients. The distributions of the granulocytes over filter depth were fitted to theoretical functions composed by 1–3 Gaussian distributions, representing subpopulations. The results showed that the neutrophils migrated as two discrete subpopulations during chemokinetic stimulation (a constant concentration of f-MLP). One of the subpopulations showed less active and passive (slow sedimentation under the influence of gravity) translocation. The most mobile subpopulation was divided into two new subpopulations when exposed to chemotactic stimulation (concentration gradient of f-MLP), one of which responded chemotactically and one of which migrated in random directions. The properties of the different subpopulations where characterized in terms of diffusion coefficient (random migration), convection velocity (chemotactic migration) and sedimentation coefficient (passive translocation).